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Transcription

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Report
from the Norwegian Genetic Resource Centre,
Norwegian Forest and Landscape Institute
03/2012
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STATE OF FOREST GENETIC
RESOURCES IN NORWAY
Norwegian Country Report to the preparation of the
FAO Report on The State of the World’s
Forest Genetic Resources
-----------------------------------------------------------------------------------------------------------------
Tore Skrøppa
Report from Norwegian Genetic Resource Centre
03/2012
Norwegian Forest and Landscape Institute
STATE OF FOREST GENETIC RESOURCES
IN NORWAY
Norwegian Country Report to the preparation of the FAO Report
on The State of the World’s Forest Genetic Resources
Tore Skrøppa
ISBN: 978-82-311-0153-6
ISSN: 1891-7933
Cover Photo: Arne Steffenrem, Norwegian Forest and Landscape Institute
Norsk institutt for skog og landskap, Pb. 115, NO-1431 Ås
i
PREFACE
The FAO Commission on Genetic Resources for Food and Agriculture at its Eleventh
Regular Session in 2007 acknowledged the urgency to conserve and sustainably utilize
forest genetic resources to support food security, poverty alleviation and environmental
sustainability, and approved the inclusion of forest genetic resources in its Multi-Year
Programme of Work. The Commission decided at its Twelfth Regular Session in 2009 that
a report on The State of the World’s Forest Genetic Resources should be prepared by
2013 and that the World Report should be based primarily on Country Reports, with
support from thematic studies and reports from international organisations.
The Norwegian Country Report has been prepared during 2011 at the Norwegian Genetic
Resource Centre in accordance with the guidelines provided by FAO. It presents the forest
sector in Norway and addresses the current state of knowledge of forest genetic diversity.
It provides data and information on current management practises regarding forest genetic
resources, in situ and ex situ conservation activities and the national tree breeding
programme. A presentation is given of the national programme on forest genetic resources
and of international cooperation.
The report has been prepared by senior scientist Tore Skrøppa.
Norwegian Genetic Resource Centre
February 2012
Nina Hovden Sæther
Director
ii
EXECUTIVE SUMMARY
Forests and wooded land cover 39 % of the land area of Norway and productive forest
amounts to 8.3 million hectares. Two conifer species, Picea abies and Pinus sylvestris,
dominate the forest area; they cover 71 % of the forest area and 84 % of total volume. The
annual harvest is at present less than 50 % of the annual increment. Forestry and the
wood industry have great financial importance in Norway, and timber and wood products
have a gross value of 5 % of the total gross domestic product. Forestry is characterized by
small-scale properties which to a large extent are privately owned.
The main objective of the forest policy is to promote sustainable forest management with a
view to promote active, local and economic development, and to secure biological
diversity, considerations for the landscape, outdoor recreation and the cultural values
associated with the forest. Forest management plans are important instruments to obtain
these goals. Three targeted programmes have high priority in the present forest policy:
forests and climate, increased use of wood and bioenergy. Active use of the forest genetic
resources may contribute to the success of these programmes.
Species composition and distribution of forest trees in Norway is largely determined by the
following factors: the invasion of tree species after the Ice Age, subsequent climatic
changes and human activities. Twenty-five of the 34 native forest tree species have their
northern limit in this country. The genetic resources of 18 species are considered to be
exposed or threatened either at the local or national level. Genetic information is provided
at some level for either morphological, adaptive or production traits or by molecular
characterization, for 11 of the native and for 11 exotic tree species. Picea abies is the
species that is best characterized both at provenance, family and clonal level. There is a
lack of knowledge of the implications of factors that may influence the genetic diversity of
the forest tree species.
In situ conservation of genetic resources of forest tree species is done in nature reserves,
and 22 gene conservation units in such reserves, comprising nine species, have been
identified and included in the European database EUFGIS. More species should be
included in the in situ conservation programme in nature reserves, and a better cooperation is needed between local and regional managers of both protected areas and
forests.
Ex situ conservation of forest genetic resources in Norway is performed by collections in
arboreta and botanical gardens; long-term tests of clones, families and provenances in
research plantations; progeny tests, clonal archives and seed orchards belonging to the
national breeding programme; and storage of seed lots for forest regeneration. It is
proposed that seed samples of selected forest tree species should be deposited and
stored in Svalbard Global Seed Vault. Evaluations should be made to assess which
material should have highest priority in ex situ conservation, and strategies should be
developed for long-term maintenance of ex situ conservation field plantations.
The Norwegian forests are regenerated both by natural and artificial regeneration. The
number of seedlings planted, of which 90 % are Picea abies, has been strongly reduced
during the last eight years, and more than 75 % of the seeds sold of this species is
produced in seed orchards. Regulations are given for regional transfer of seed lots. A
revised tree breeding strategy has been developed, with emphasis on Picea abies. All
seed orchards are first generation, and their breeding objectives are to improve climatic
iii
adaptation, growth and quality, without decreasing the genetic variation in future forests.
Most breeding populations consist of local material. The national strategy to increase CO2
sequestration by greatly augmenting the number of genetically improved seedlings planted
will require a considerable increase in resources invested into tree breeding and
associated breeding research.
The national programme on forest genetic resources is administered by the Norwegian
Genetic Resource Centre, based on advice from the advisory committee on forest genetic
resources. In the present period, planned actions are in four major areas: generate
knowledge and monitor processes influencing genetic resources; ex situ and in situ
conservation activities; sustainable use and development of forest genetic resources and
networking, coordination and dissemination of knowledge about forest genetic resources
and raising public awareness. A network of partner institutions contributes to the activities.
No specific courses are given at the universities on management and conservation of
forest genetic resources. Public awareness of the values related to forest genetic
resources has increased significantly in Norway during the last five year period. However,
it will continuously be necessary to educate managers of forests and natural resources
about the importance of forest genetic resources, and in particular, how to choose adapted
reproductive materials under the changing climate conditions.
Norway takes actively part in regional and global cooperative programs on forest genetic
resources. The Nordic Genetic Resource Center is important at the regional level, and its
forest sector, NordGen Forest, is located in Norway. In the period 2008-2011, Norway held
the chairmanship and secretariat (Liaison Unit) of FOREST EUROPE and is from 2011 a
bureau member of the Intergovernmental Negotiating Committee for a Legally Binding
Agreement on Forests in Europe. Further cooperation both at the regional and European
level is needed in the management of forest genetic resources under climate change. It is
then important to maintain the networks that have been established in common research
and development projects.
Significant legislation regulating conservation and use of forest genetic resources in
Norway is the Forestry Act of 2005 and the Nature Diversity Act of 2009. A regulation
mandated in the Forestry Act assures that reproductive material of high quality and
adapted to planting site is being used in regeneration and that a high level of genetic
diversity is maintained in the forest. The Nature Diversity Act regulates the import and
planting of alien tree species and also access, property rights and exchange of genetic
resources. At present, there is a policy of free access to forest genetic material for seed
production and tree breeding, and also a free exchange of forest reproductive material
between the neighboring countries. This is recommended to be continued.
Promoting sustainable development and poverty reduction is an overriding objective of
Norwegian foreign and development policy. One major element of this policy is the
Government of Norway’s International Climate and Forest Initiative, in which Norway is
prepared to allocate up to NOK three billion per year to efforts to reduce greenhouse gas
emissions from deforestation in developing countries.
Key Words:
Forest genetic resources, in situ conservation, ex situ conservation, tree
breeding, national programme, international cooperation
iv
SAMMENDRAG
Av det totale landområdet I Norge er 39 % dekket av skogtrær, og av dette er 8,3 millioner
hektar produktivt skogareal. To bartrær, gran (Picea abies) og furu (Pinus sylvestris) er
dominerende i skogen; de dekker 71 % av skogarealet og 84 % av totalt stående volum.
Det hogges nå mindre enn 50 % av den årlige tilveksten. Skogbruk og skogsindustri har
hatt, og har fortsatt, stor økonomisk betydning i Norge, og tømmer og produkter fra skogen
utgjør 5 % av det totale nasjonalproduktet. I skogbruket er det et stort antall mindre
eiendommer som hovedsakelig er eid av privatpersoner.
Et viktig formål i skogpolitikken er å fremme en bærekraftig forvaltning av skogressursene
med sikte på aktiv lokal og nasjonal verdiskapning, og å sikre biologisk mangfold, hensyn
til landskapet, friluftslivet og kulturverdiene i skogen. Skogbruksplaner er viktige for å
oppnå dette. Tre målrettede programmer har høy prioritet I dagens skogpolitikk: skog og
klima, økt bruk av tre og bioenergi. Bærekraftig bruk av skogtrærnes genetiske ressurser
kan bidra til gjennomføringen av programmene.
Utbredelsen av de ulike treslag i Norge og hvor de vokser i landskapet, er hovedsakelig
bestemt av følgende faktorer: innvandringen av trær etter siste istid, senere endringer i
klimaet og menneskelige aktiviteter. Av de 34 treslagene som regnes som naturlige i
Norge, vokser 25 på sin nordgrense her i landet. De genetiske ressursene til 18 treslag
vurderes som utsatt eller truet enten på lokalt aller nasjonalt nivå. Vi har kunnskap om
genetisk variasjon på ett eller flere nivåer for morfologiske, adaptive eller
produksjonsegenskaper eller gjennom molekylær karakterisering for 11 av de naturlige
treslagene og for 11 innførte treslag. Gran er det treslaget som er best karakterisert
genetisk både for provenienser, familier og kloner. Vi har ikke tilstrekkelig kunnskap om
betydningen av de ulike faktorene som påvirker treslagenes genetiske diversitet.
In situ bevaring av trærnes genetiske ressurser gjøres i verneområder, og 22
naturreservater med ni treslag er valgt ut og definert som genressursreservat. De er
inkludert i et felles europeisk samarbeid om slike områder og er inkludert i en felles
database EUFGIS. Flere treslag bør inkluderes i planen for bevaring av trærnes genetiske
ressurser i naturreservater, og et bedre samarbeid er nødvendig mellom lokal og regional
forvaltning av både verneområder og skog.
Ex situ bevaring av skogtrærnes genetiske ressurser i Norge gjøres i samlinger i arboreter
og botaniske hager; i plantefelt med kloner, familier og provenienser i langsiktige forsøk i
genetisk forskning; i avkomforsøk, klonarkiv og frøplantasjer i foredlingsprogrammer for
skogtrær og gjennom lagring av frøpartier for foryngelse av skogen. Det foreslås at
frøpartier for langsiktig lagring og bevaring skal legges inn i Svalbard globale frøhvelv. Det
er behov for å evaluere hvilke treslag som bør ha høyeste prioritet i ex situ bevaring, og
strategier bør legges for langsiktig skjøtsel og bevaring av plantefelt som en del av ex situ
bevaringen.
Ny skog etableres i Norge både ved naturlig foryngelse og ved planting. Mer enn 90 % av
plantene som settes ut er gran, og mer enn 75 % av granfrøet som selges er produsert i
frøplantasjer. Det totale antallet av planter har blitt sterkt redusert de siste årene. En
forskrift regulerer bruken av skogfrø og inneholder også regler for flytting av frøpartier. En
ny strategi for planteforedling av skogtrær er lagt fram, med gran som det viktigste
treslaget i foredlingen. Alle frøplantasjer er av første generasjon, og det legges i
foredlingen vekt på god tilpasning til klima og forbedret vekst og kvalitet, uten at den
v
genetiske variasjon blir vesentlig redusert i framtidsskogen. Foredlingspopulasjonene
består i hovedsak av norske materialer. Den nasjonale strategien om å øke CO2 opptaket
gjennom å plante et større antall genetisk forbedrete planter vil kreve en betydelig økning
av ressurser til foredlingsarbeidet og til foredlingsforskningen.
De nasjonale aktivitetene for bevaring og bruk av skogtrærnes genetiske ressurser ledes
av Norsk genressurssenter. Genressursutvalget for skogtrær er et rådgivende organ i dette
arbeidet. I perioden 2011-2014 er aktivitetene konsentrert om følgende hovedområder:
generere kunnskap og overvåke prosesser som påvirker genetiske ressurser; aktiviteter
inn in situ og ex situ bevaring; bærekraftig bruk av trærnes genetiske ressurser;
nettverksaktiviteter og spredning av kunnskap om trærnes genetiske ressurser og deres
betydning. Mange institusjoner deltar i dette arbeidet. Ved universitetene gis det ingen
spesielle kurs i bevaring og skjøtsel av trærnes genetiske ressurser. I den siste tiden har
det blitt økt oppmerksomhet om betydningen av disse ressursene. Det vil fortsatt være
nødvendig å gi informasjon om dette temaet til forvaltning og næring, og spesielt om
optimale valg av formeringsmaterialer i et endret klima.
Norge deltar aktivt i regionale og internasjonale aktiviteter omkring skogtrærnes genetiske
ressurser. På nordisk nivå er Nordisk Genressurssenter (NordGen) en viktig organisasjon
som har sitt sekretariat i Norge. I perioden 2008-2011 var sekretariatet til FOREST
EUROPE i Norge, og det europeiske skogsamarbeidet ble ledet herfra. Norge er fra 2011
medlem av den internasjonale komitéen som skal legge fram et forslag om en mulig rettslig
bindende avtale på skog i Europa. Det er behov for et videre samarbeid om bevaring og
bruk av skogtrærnes genetisk ressurser i Europa, spesielt i et endra klima, og nettverkene
som er blitt etablert omkring forskning og utviklingsarbeid må opprettholdes.
Den viktigste lovgivningen for bevaring og bruk av skogtrærnes genetiske ressurser er
Skogbruksloven fra 2005 og Naturmangfoldloven fra 2009. Forskrift om skogfrø og
skogplanter, hjemlet i Skogbruksloven, sikrer av plantematerialer er av høy kvalitet og godt
tilpasset til planteplassen og at tilstrekkelig genetisk variasjon opprettholdes i skogen.
Naturmangfoldloven regulerer import og utsetting av utenlandske treslag og sikrer også
tilgang, rettigheter og utveksling av genetiske ressurser. Det er fri tilgang til genetiske
materialer til frøproduksjon og foredlingsvirksomhet, og fri utveksling av frø og planter
mellom naboland. Det anbefales at denne ordningen opprettholdes.
Det er en overordnet holdning i norsk utenrikspolitikk å fremme bærekraftig utvikling og
reduksjon av fattigdom. Et viktig element i denne politikken er regjeringens klima og
skogprosjekt som går ut på at Norge vil bevilge inntil 3 milliarder kroner årlig til arbeid mot
klimagassutslipp fra avskoging i utviklingsland.
.
Nøkkelord:
Skogstrærnes genetiske ressurser, in situ bevaring, ex situ bevaring,
skogplanteforedling, nasjonale program, internasjonalt samarbeid,
vi
CONTENT
Preface ................................................................................................................................ ii
Executive Summary............................................................................................................ iii
Sammendrag ...................................................................................................................... v
Introduction to the Forest Sector in Norway ....................................................................... 1
1.
1.1.
Natural conditions ................................................................................................................ 1
1.2.
Forestry in Norway .............................................................................................................. 3
2.
The Current State of Forest Genetic Resources ................................................................ 7
2.1.
Native forest tree species .................................................................................................... 8
2.2.
Genetic knowledge ............................................................................................................11
2.3.
Factors influencing the genetic diversity and lack of knowledge .....................................14
3.
The state of in situ Genetic Conservation ........................................................................ 15
4.
The state of ex situ Genetic Conservation ....................................................................... 19
5.
The State of Use and Sustainable Management of Forest Genetic Resources .............. 25
5.1.
Reproductive material in use.............................................................................................26
5.2.
Tree improvement programmes and their implementation ..............................................30
6.
The State of National Programmes, Research, Education, Training and Legislation ...... 35
6.1.
National programme on forest genetic resources ............................................................35
6.2.
Partners in the national FGR programme.........................................................................37
6.3.
Research, education and training .....................................................................................38
6.4.
National legislation ............................................................................................................39
6.5.
Public awareness ..............................................................................................................40
The State of Regional and International Agreements and Collaboration ......................... 41
7.
7.1.
Nordic cooperation ............................................................................................................41
7.2.
European networks ...........................................................................................................42
7.3.
International programmes and agreements ....................................................................42
7.4.
Benefits and needs in regional and international cooperation .........................................43
8.
Access to Forest Genetic Resoruces, Sharing of Benefits .............................................. 44
9.
Contribution to Food Security, Poverty Allevation and Sustainable Development .......... 46
Acknowledgement ............................................................................................................ 47
vii
viii
1. INTRODUCTION TO THE FOREST SECTOR IN NORWAY
1.1. Natural conditions
Norway is Europe’s northernmost country, ranging over some 1750 km between 58 °N and
71 °N. The country’s total area is 323,787 km2 (excluding the islands of Svalbard and Jan
Mayen). Its population is 4.9 million, with a population density of 15 people per km2.
The total area covered by forests and wooded land is 13.4 million hectares and constitutes
39 % of the land area in Norway. Of this 8.3 million hectares are productive forest land, that
is to say forest areas that can produce more than 1 m3 per hectare per year. Mountains,
extensive grazing and other outlying land, lakes and built-up areas account for 57 % of the
land area.
Figure 1. Map showing the forest area and other types of land in Norway.
Source of map: Norwegian Forest and Landscape Institute.
1
Norway has substantial north-south and east-west climate gradients. Inland areas in northern
and eastern Norway have a typical continental climate, with warm summers and cold winters.
The entire coastline is characterised by a maritime climate, with relatively cool summers and
mild winters.
Annual precipitation also varies. The zone with the highest annual rainfall lies about 30-40
km inland from the coast. The driest areas are the inland regions of Finnmark (in the far
north), as well as parts of the valleys of eastern Norway. The length of the growing season,
defined as the number of days with a mean temperature of more than 5 °C, varies between
200 days in south-western Norway and 100 days along the coast of eastern Finnmark. In the
alpine regions, the growing season is even shorter.
The soil and topography of the Norwegian land area has, in addition to the climatic
conditions, had a great impact on the extent of the forests, species composition and growth.
The far largest portion of the forests is boreal coniferous forest with principal species Norway
spruce (Picea abies) and Scots pine (Pinus sylvestris), and with downy birch (Betula
pubescens) and silver birch (B. pendula) as the dominating deciduous tree species. Boreal
deciduous forests are an important component of the forests at high altitudes and in the
northern areas. Hardwood forests which constitute, only 1 % of the forest area, occur in the
southern part of the country and in particular along the coast, while the coniferous forests
dominate in the inland.
The current forest composition is greatly influenced by different human-forest interactions.
During several centuries the forests have suffered from deforestation, and much of the
present forests are the results of human-induced regeneration and various silvicultural
treatments. The species composition and structure of the present forests in all ecological
zones is thus significantly different from primeval forests.
Image 1. A Norwegian forest landscape. Photo: Bård Løken, Samfoto.
2
1.2. Forestry in Norway
The forests are of great importance for the Norwegian society. They provide a whole range of
ecosystem services that contribute to the living environment and social welfare as well as
economic development. The forest resources are of great historical importance and have
played a major role in developing trade and industry.
In 2009, the total growing stock in Norwegian forests was 823 million m3, with a yearly
increment of 25 million m3. Over the last 90 years the total annual harvest has been between
8 and 11 million m3. This is considerably lower than the yearly increment, as shown in Figure
2. With the existing level of timber harvest and forest management, the growing stock and its
increment in 2011 is more than twice the level documented by the first National Forest
Inventory in 1932. The amount of dead wood, old forest and deciduous trees, which is
important for biological diversity, has increased considerably during the same period.
Figure 2. Annual increment and harvest in Norwegian forests 1919-2009.
Norwegian forestry and the wood industry continue to have great financial importance today,
at a national, regional and local level. The primary value of Norwegian timber was 3 billion
NOK (US$ 535 million) in 2008. The same year timber and wood products had a gross value
of approximately 48 billion NOK (US$ 8.6 billion), corresponding to 5 % of the total gross
domestic product in Norway. Approximately 50 % of the wood of the two conifers harvested
is sold to the timber and wood industry and 50 % to the pulp and paper industry. Biomass
and timber from Norwegian forests will continue to play an important role in the years to
come, as renewable resources that can help us meet the challenges of climate change.
Forestry in Norway is characterized by small-scale properties, combining forestry and
agriculture. This structure is based on the Norwegian topography, varying production
conditions and the ownership structure of Norwegian forests. In 2009, Norway had
120.000 forest owners with more than 2.5 hectares of forest. Of these properties, 97 % are
privately owned, and constitute 80 % of the total productive forest area. The average size of
privately owned farms with forest resources is 45 hectares. Figure 3 shows the percentage
distribution of forest ownership by area.
3
Figure 3. The percentage distribution of forest ownership by area.
The Norwegian Ministry of Agriculture and Food is the national authority responsible for the
Norwegian forest policy which is based on a wide range of measures, including legislation,
taxation, financial support schemes, research and advisory bodies. The main objectives of
the Forestry Act of 2005 are to promote sustainable forest management with a view to
promote active, local and economic development, and to secure biological diversity,
consideration for the landscape, outdoor recreation and the cultural values associated with
the forest. The Forestry Act applies to all categories of forest ownership. Protective forests,
which comprise approximately 20 % of the Norwegian forest area, are regulated in the
Forestry Act. The main function of a protective forest is to protect climatically vulnerable
forests and other forests against damage, and includes mainly the forest bordering mountain
areas.
The National Forest Inventory has been an important basis for the development of forest
policy since the beginning of the last century, and is repeated for every county in Norway in
five year intervals.
A regulation under the Forestry Act requires forest owners to reinvest a part of the revenue
from forestry into a government administrated fund; the Forest Trust Fund. This fund was
established to secure long term investment in sustainable forest management such as
silviculture, building and maintenance of infrastructure, forest management planning and
environmental measures. From the genetic resource point of view, this fund has in particular
been important for contributing to the reestablishment of forests after harvest with proper
reproductive material.
Norwegian forest policy, as well as the environmental standards that forest owners are
committed to follow, emphasise environmental considerations, such as maintaining and
developing biological diversity, and the social and cultural functions of forests. The share of
virgin forests is small in Norway. Today there are therefore strong concerns that Norwegian
forestry is environmentally sustainable and takes sufficient consideration of biological
diversity and threatened habitats. Biodiversity rich habitats are registered and mapped in
4
forest management plans. This registration is being done according to a standardized and
well documented system.
Forest management plans are important tools for the forest owner, in order to promote
sustainable forest management. This includes both active commercial use of the forest
resources as well as the forest owner’s responsibility for the protection of biological diversity,
landscapes, recreation and cultural values in the forest. Forest management plans are
offered to all forest owners in Norway every 10th to 15th year according to plans at county
level. Today, forest management plans are developed through analysis and descriptions
based on aerial photography supporter field inventories on ground and laser scanning. Field
registrations are also important. The final product is customized to the individual forest owner
and can give him or her recommendations for forestry measures. Providing an inventory of
forest resources and environmental values on the property is a precondition for the allocation
of grants.
Important areas for biological diversity are being inventoried on the basis of knowledge about
species and their habitat requirements. The environmental inventories developed through the
forest management planning process are made publicly available. The forest owner must
ensure that all activities in the forest are carried out in compliance with laws and regulations.
Under the Forestry Act, every forest owner must have an overall view of the environmental
values and pay regard to them when carrying out activities in the forest.
The right of public access to outlying land, including forests, is an old and important principle
in Norway. The general public may use the forests for recreational activities and sports at
any time of year. The principle of public access is underlined by the forest policy and the
environmental standards used by forest owners. Traditional activities such as skiing, hunting,
fishing, berry picking and mushrooming are still important, while modern activities such as
off-road biking are increasingly popular. Norwegian forests are often mentioned as important
for public health and as an educational arena for children and youth. Using the forests for
recreation and sports is considered to have a positive impact on both physical and mental
health.
Image 2. Cross country skiing is
a popular recreation activity in the
Norwegian forests. Photo: Svein
Skøien, Norwegian Institute of
Agricultural and Environmental
Research.
5
Forest genetic resources are considered important both as one element of the biological
diversity that should be conserved for future generations and as the basis for the supply of
forest reproductive material for the regeneration of forest after harvest. In the present
Norwegian forest policy the genetic resources may contribute to the success of targeted
programmes that have high priority: Forests and climate; increased use of wood and
bioenergy.
Growing forests capture CO2, and active management of forests resources may play an
increasing part in reducing CO2 emission. The Norwegian forests annually capture and store
more than 50 % of the national CO2 emissions. A Governmental White Paper in 2009
proposes climate policy instruments with a view to increase the use of forest resources to
mitigate CO2 emissions by means of sustainable, active forestry, including forest tree
breeding and planting of genetically superior reproductive material.
An important goal for both the Government and the wood processing industry is to increase
the use of wood wherever it can replace materials with more negative environmental impact.
The Norwegian Wood-based Innovation Scheme is an important initiative that addresses
different parts of the market: Companies, decision-makers, architects, entrepreneurs,
traders, research and innovation. The Bio-energy Scheme was established in 2003 and its
budget has been tripled to increase awareness of climate change and forests as a source of
carbon-neutral energy. The forest genetic resources can make contributions to both
initiatives.
The Norwegian Government will adapt a proactive and integrated approach to forestry issues
in international forestry and environmental policy work, taking as a point of departure that a
more central place must be given to forestry in future international legislation on climaterelated issues.
.
Image 3. The forests are an important source for bioenergy.
Photo: Arne Steffenrem, Norwegian Forest and Landscape
Institute.
6
2. THE CURRENT STATE OF FOREST GENETIC RESOURCES
The Norwegian forests can broadly be classified into three major types: coniferous evergreen
boreal forest, broadleaved forest and mixed forest (Table 1). In addition to the 12 mill
hectares of forests, other wooded land amounts to 1.4 mill hectares. The forests are to a
large extent formed by two conifers, Picea abies (Norway spruce), and Pinus sylvestris
(Scots pine), and the two birch species Betula pendula and B. pubescens. The two conifers
are economically the most important species and are the only species actively managed for
wood production in the commercial forestry; together they cover 71 % of the forest area and
97 % of the annual harvest. Actual data related to the distribution of tree species in Norway
is presented in Table 1.
Pinus sylvestris is mainly naturally regenerated, while Picea abies is planted on
approximately 50 % of the harvested forest area. The number of seedlings planted of this
species annually is at present 23 million, which is only a third of the number planted 30 years
ago. The major part of spruce seedlings planted is of native origin. Exotic conifer species
have been tested in experiments since the beginning of the 20th century, but except for the
planting of Picea sitchensis and the hybrid P. sitchensis x P. glauca along the coast in central
and northern Norway, no exotic species are used to any large extent in the commercial
forestry. Very few broadleaved trees are planted for wood production. However, several of
these species are used for landscaping, along roads and in parks and gardens.
Table 1. Major forest type categories and main tree species.
Major Forest Types
Area covered
hectares
Coniferous evergreen forest
5.5 mill
Broadleaved forest
4.5 mill
Mixed forest
2.0 mill
Main species
Picea abies,
Pinus sylvestris
Betula pubescens,
B. pendula
P. abies, P. sylvestris,
B. sp.
Image 4. A Scots pine production stand in Norway. Photo: Norwegian Forest and Landscape Institute.
7
Figure 4. Distribution of tree species in Norway.
2.1. Native forest tree species
Species composition and distribution of forest trees in Norway are largely determined by the
following factors: the invasion of tree species after the Ice Age, subsequent climatic changes
and human activities. The first tree species to establish after the ice retreated more than
10,000 years ago were birch (Betula pubescens), poplar (Populus tremula) and Scots pine
(Pinus sylvestris). These species spread fast and to altitudes 200-300 m higher than the
present timber line. During the warm and dry period that later followed high temperature
demanding species such as lime (Tilia cordata), ash (Fraxinus exelsior) and oak (Querqus
robur, Q. petrea) spread and formed forests in the southern and southwestern part of the
country. Small remnants of these forests still exist. These and other deciduous tree species
that occur as scattered trees in mixed stands with other species (e.g. Fagus silvatica, Ulmus
glabra, Acer platanoides, Prunus avium) have their main distribution in warmer climates at
more southern latitudes and occur in Norway today at the northernmost border of their
natural range.
Image 5. Most likely the northernmost population of Fraxinus
excelsior in the world, lat. 63°40’. Photo: Arne Steffenrem,
Norwegian Forest and Landscape Institute.
8
Figure 5. Map of fossil pollen for the inference of Holocene expansion in Picea abies. The map show
interpolated age (in time intervals of 1000 years before present) of Picea abies fossil pollen (threshold >= 2%).
Map developed by Christoph Sperisen, Federal Institute for Forest, Switzerland.
It was not until approximately 2,500 years ago, during a cooler and more humid period, that
the conifer Picea abies started to form forest in Norwegian landscape (Figure 5). The Picea
abies spruce populations have their origin in the Russian planes, and most likely also from
the Baltic area. During a period of 7,000 years the species spread through Finland and
northern Sweden, and also from the Baltic area through southern Sweden to southern
Norway. The invasion of the south-eastern lowland area started 3,000 years ago, but the
migration up the valleys to the species' present altitudinal boundary was not completed until
the period 1,000-1,500 AD. The coastal spruce forest in Central Norway established rather
late (approx. 1,300 AD). The present natural occurrence of Norway spruce is in southeastern Norway from the sea level and up to 1000 m, and in Central and North Norway, north
to lat. 67°N, at decreasing altitudes in the north. Outside this area the species has been
planted both in western Norway and north of its natural boundary in northern Norway in the
last century. In both regions it has become an important timber species.
9
An evaluation has been made of the native forest trees species in Norway with a description
of life history traits such as geographic range, occurrence, pollination vector and seed
dispersal. Based on this information, and known genetic knowledge, of the species their
genetic resources were characterised as vital, uncertain, exposed and threatened. This
information is presented in Table 2. Special for Norway is that 25 of the 34 native species
have their northern limit in this country. Of the Sorbus species, seven are endemic in
Norway. Eight of these species characterised as exposed or threatened are included in the
Norwegian Red List for Species.
Twelve widely distributed species with generally effective dispersal of pollen and seeds were
considered vital (e.g. Betula spp., Alnus incana, Pinus sylvestris, Picea abies) and have as
such no particular conservation requirements. Five species were considered uncertain
(Quercus spp, Fraxinus excelsior, Acer platanoides, Fagus sylvatica) because of limited
ranges, scattered occurrences and possibly less effective dispersal of seeds and/ or pollen
than the former group. Fifteen species were considered exposed (10 Sorbus spp., Malus
sylvestris, Prunus avium, Tilia cordata, Taxus baccata, Ilex aquifolium) owing to marginal
occurrences, a great proportion of insect-pollination (all except for Taxus baccata and Ilex
aquifolium), limited sexual reproduction (Tilia cordata), and endemism (some Sorbus spp.).
Only Ulmus glabra was classified as endangered because of the Dutch Elm disease that may
reduce the genetic variability at the population level. Human influence has minor impact on
the above classification.
Image 6. One of the endemic Sorbus species in Norway, Sorbus meinichii
(Lindeberg ex. C. Hartman) Hedlund). It has probably originated through
one or several hybridization events between (Sorbus aucuparia L. and
Sorbus hybrida L). Photo: Per Salvesen, University of Bergen.
10
Table 2. Native forest tree species in Norway and their characteristics.
1)
2)
Species
Scientific name
Geographic
range
Occurrence
Pollination
vector
Seed
dispersal
Northern
limit in
Norway?
Picea abies
Pinus sylvestris
Juniperus
communis
Taxus baccata
Salix caprea
Populus tremula
Betula pendula
Betula pubescens
Alnus incana
Alnus glutinosa
Coryllus avellana
Prunus padus
Fagus sylvatica
Quercus robur
Widespread
Widespread
stand
stand
wind
wind
Wind
Wind
Widespread
Limited
Widespread
Widespread
Widespread
Widespread
Widespread
Medium
Medium
Widespread
Marginal
Limited
scattered
scattered
scattered
stand/scattered
stand/scattered
stand/scattered
stand/scattered
stand/scattered
stand/scattered
scattered
stand/scattered
stand/scattered
wind
wind
insect
wind
wind
wind
wind
wind
wind
insect
wind
wind
yes
yes
yes
Quercus petraea
Limited
stand/scattered
wind
Acer platanoides
Fraxinus excelsior
Ilex aquifolium
Malus sylvestris
Limited
limited
limited
limited
scattered
stand/scattered
scattered
scattered
insect
wind
wind
insect
Prunus avium
Tilia cordata
Ulmus glabra
Sorbus aucuparia
Sorbus hybrida
1)
Sorbus meinichii
1)
Sorbus subsimilis
Sorbus
1)
subpinnata
Sorbus
1)
subarranensis
1)
Sorbus neglécta
1)
Sorbus lancifólia
1)
Sorbus norvegica
Sorbus rupicola
Sorbus intermedia
Sorbus aria
marginal
limited
medium
widespread
limited
marginal
marginal
marginal
scattered
stand/scattered
stand/scattered
scattered
scattered
scattered
scattered
scattered
insect
insect
wind
insect
insect
insect
insect
insect
Birds
Birds
Wind
Wind
Wind
Wind
water/wind
water/wind
mammals
Birds
Birds
mammals/
birds
mammals/
birds
Wind
Wind
Birds
mammals/
birds
Birds
Wind
Wind
Birds
Birds
Birds
Birds
Birds
marginal
scattered
insect
marginal
marginal
marginal
limited
marginal
marginal
scattered
scattered
scattered
scattered
scattered
scattered
insect
insect
insect
insect
insect
insect
yes
Genetic
resource
category
vital
2)
vital
yes
yes
yes
yes
vital
exposed
vital
vital
vital
vital
vital
vital
vital
vital
uncertain
uncertain
yes
uncertain
yes
yes
yes
yes
uncertain
exposed
exposed
exposed
yes
yes
yes
yes
yes
yes
yes
exposed
exposed
threatened
vital
exposed
exposed
exposed
exposed
Birds
yes
exposed
Birds
Birds
Birds
Birds
Birds
Birds
yes
yes
yes
yes
yes
yes
threatened
threatened
exposed
exposed
exposed
exposed
Species that are considered to endemic in Norway
Pinus sylvestris ssp. lapponica is rated as near threatened in The Norwegian Red List for Species
2.2. Genetic knowledge
The first provenance and species trials with both native and introduced tree species, in
particular conifers, were planted in Norway approximately 100 years ago. Since then, short
and long term field tests with both native and introduced species have provided knowledge
about genetic differences between species and of the within-species genetic variability
among provenances, populations within provenances and within populations. Studies have in
particular been made of traits that characterise adaptation to the climatic conditions. More
recently, molecular genetic studies have been initiated, at present in eight native and one
11
introduced species (Table 3). Forest tree species, both native and introduced, from which
genetic knowledge is available, are listed in Table 3. Norway spruce is the only species that
has a sufficient genetic characterisation at the provenance, family and individual level.
Genetic diversity in Picea abies
Recent molecular studies confirm that the vast northern range of Picea abies was colonized
from a single Russian refugium and that the expansion westward took place along two main
migration routes. Populations in southern Norway show relatively high levels of diversity
compared to those of the northern one. In the north, limited seed and pollen production may
have caused decreased diversity and increased inbreeding, reflecting the marginality of the
species in the north.
Genetic information characterising adaptation of Norway spruce to the climatic conditions is
available from provenance, progeny and clonal trials. Measurements have in particular been
made of annual growth rhythm traits: the timing and duration of the annual growth period,
frost hardiness development in the autumn and dehardening in the spring, and the
occurrence of climatic damage under field conditions. All studies demonstrate a clinal
variation in growth rhythm traits in natural populations from the south to the north and from
low to high altitudes. The southern and lowland populations have the longest duration of
growth season, and as a consequence, the highest growth potential. They also develop
latest autumn frost hardiness. The only well-known characterisations of the adaptive process
of spruce populations are the responses to temperature and photoperiod. Within natural
populations, a large genetic variation is present, also for traits that show clinal variation at the
provenance level and in populations at the geographic margin of the species.
In addition, a number of studies have shown that trees of Picea abies can adjust the
performance in adaptive traits by a rapid and likely epigenetic mechanism, through a kind of
a long-term memory of temperature sum and photoperiod during seed production. These
effects may have important implications for both gene conservation and for practical forest
tree breeding. The research on epigenetic effects on adaptive traits in Picea abies has high
priority.
The genetic knowledge of intraspecific genetic variation patterns obtained in research is
published in international and national research journals and in more popular national forest
journals. It is also regularly disseminated at meeting and conferences for foresters. Major
users are the national tree breeding organisations and advisors in forestry and natural
resource management at the regional and national level.
Image 7. Clouds of pollen from Picea abies stands. Photo:
Ragnar Johnskås, The Norwegian
Forest Seed Center.
12
Table 3. Forest species for which genetic variability has been evaluated at different genetic levels.
Species
Scientific name
Picea abies
Native (N)
or
exotic(E)
N
Type of
material
evaluated,
genetic level
Morphological
traits
Adaptive and
production
characters
assessed
Molecular
characterization
X
X
X
X
X
X
X
X
X
X
X
Pinus sylvestris
N
Betula pendula
N
Alnus glutinosa
N
Acer
platanoides
Fraxinus
excelsior
Sorbus
aucuparia
Ulmus glabra
N
Malus
sylvestris
Taxus baccata
N
provenances,
families,
clones
provenances,
families
provenances,
families
provenances,
families
provenances,
families
provenances,
individuals
provenances,
families
provenances,
families
individuals
N
provenances
X
Fagus sylvatica
N
provenances
X
Picea
sitchensis
Picea lutzii
E
X
X
X
X
Picea
engelmanni
Picea glauca
E
provenances,
families
provenances,
families
provenances
X
X
E
provenances
X
X
Picea mariana
E
provenances
X
X
Pinus contorta
E
X
X
Abies
lasiocarpa
Abies
nordmanniana
Abies amabilis
E
X
X
E
provenances,
families
provenances,
families
provenances,
X
X
E
provenances
X
X
Abies procera
E
provenances
X
X
Pseudotsuga
menziesii
E
provenances
X
X
N
N
N
E
X
X
X
X
X
X
X
X
X
13
X
2.3. Factors influencing the genetic diversity and lack of knowledge
Generally, there is a lack of knowledge of the importance and implications of factors that may
influence the genetic diversity of the forest tree species. Fragmentation of the landscape
reduces the gene flow among individuals and populations which may lead to a smaller
effective population size and increased degree of inbreeding. The gene flow among
populations has been characterised for very few tree species with a fragmented distribution
in Norway. For many tree species regeneration is hindered by browsing of increasing
population sizes of wild animals such as moose and red deer, e. g. browsing on Taxus
baccata. Change in land use and clogging influence the growth conditions, in particular for
the hardwood broadleaved species, and may change the competitive environment. Pests
and diseases, which may be more common due to warmer climate at northern latitudes, may
lead to loss of populations and thereby reduced diversity for some species. The implications
of climate change on the forest genetic resources are not well understood, in particular as
the prediction of the future climatic conditions is uncertain. More information should be
generated about the influence of these factors, and their interactive effects, on the forest
genetic diversity. In general, prospects for future conditions are good, but pest and diseases
(e. g. ash decline), perhaps associated with climate change, and browsing pressure appear
to be the main obstacles today.
During the period 1950 -1980 Central European provenances of Picea abies spruce were
planted to a large extent in southern Norway. Both practical experience and results from
surveys showed that this was a bad choice of provenances for south-eastern Norway,
resulting in plantations with climatic damage and reduced saw timber qualities. It was feared
that gene flow from such stands would lead to a reduced adaptedness in the next generation.
Research results have shown that this may not be the case, as there seems to be a rapid
change in adaptive performance from one generation to the next in Norway spruce due to an
epigenetic mechanism.
The use of Picea sitchensis and the hybrid P. sitchensis x P. glauca along the coast of
central and northern Norway has resulted in the natural regeneration of these species on
several sites. However, this does not seem to be a threat to the native forest trees. The use
of exotic tree species in the commercial forestry is restricted and no other exotic tree species
are used to any large extent in the commercial forestry.
A survey was conducted in five counties as part of the national forest assessment in a five
year period, to monitor the extent and regeneration of eleven selected tree species. It was
found that there has been an increase in the standing volume and area of several of the
deciduous tree species. The data obtained from the survey will be a good baseline for future
monitoring of the change in the resources of these species.
Tree species that are listed on the Norwegian Red List for Species will be revaluated when
the regular updating of the list takes place, approximately every five years.
14
3. THE STATE OF IN SITU GENETIC CONSERVATION
In situ conservation of forest tree species comprises the conservation of viable populations in
their natural environment, whether it is a production forest or a protected area. The term is
often applied to naturally regenerating wild populations, and can be integrated into managed
production and multiple-use forests. The aim of in situ conservation is often to conserve the
function of an ecosystem and the evolutionary processes rather than just species. Under
certain conditions, nature-protected areas provide a significant potential for in situ
conservation of forest genetic resources. Norway has chosen a strategy to establish in situ
conservation units in protected areas for some target species. This is done as part of our
national contribution to the common European project EUFGIS (www.eufgis.org) which
created an online information system for forest genetic resources inventories in Europe,
focusing on improving documentation and management of dynamic conservation units of
forest trees.
Protected areas in Norway
Protected areas in Norway are protected through The Nature Diversity Act. Excluding the
marine reserves, there are four different types of protected areas, which differ in size,
objectives (i.e. what is protected) and management regulations.
The four types of protected areas are:
1. National parks have been established to prevent activities that could disturb unspoiled
areas of significant size, and also to protect landscapes and habitats for plants and animals.
National parks also safeguard areas for outdoor activities, nature experience and recreation.
Traditional farming and mountain dairy farming are usually allowed in a national park.
2. Nature reserves have the strictest protection regime among Norwegian protected areas.
Some reserves cover untouched nature, while others are former cultivated land. A stated
goal for these reserves is to conserve biodiversity, and vascular plants in particular, present
at the time the reserves were established. However, when areas change as a result of
succession, biodiversity will be affected and management actions may be necessary to
prevent loss of the species that initially were used for the selection of reserves. Activities that
can impact the targeted protection objectives are strictly forbidden. Moreover, there should
be management operations that can contribute to fulfill the objective for conservation of the
specific area.
3. Protected landscape areas comprise distinctive and/or beautiful natural or agricultural
countryside and often used to maintain actively used farming landscapes. Restrictions are
less severe than in other protected areas and farming and forestry can usually be continued,
though with greater attention to not reducing landscape qualities.
4. The final type of protected area, biotope reserves, protects the ecological environment of
specific plant or animal species, without protecting the corresponding area as a nature
reserve.
15
Altogether 3.1 % of the total forest area is protected through one of the first two types of
protected area. This allows the possibility to combine in situ conservation of genetic
resources with other protection objectives in already protected areas. Nature reserves was
considered to form the most relevant option for in situ conservation of forest genetic
resources because such areas are quite well documented as regards species content, size
of area, the conservation regime is quite strict, development in such areas is to some extent
monitored and some management can be allowed. Of the 2012 nature reserves in Norway,
759 reserves are in forests, covering 281 550 hectares, see Table 4. The number of reserves
in forests has increased from 412 in the last ten year period. An on-line searchable database
of all protected areas in forests, and a listing of the tree species growing there, has been
established by the Norwegian Genetic Resource Centre. It is based on, and linked to, the
database of all protected areas managed by the Norwegian Directorate for Nature
Management (Naturbase).
Table 4. Nature reserves in Norway 2010 and 2000 in forests. Source: The Directorate for Nature Management.
Forest type
Coniferous forest
Broadleaved deciduous forest
Taxus/Ilex forest
2010
Number
of reserves
438
283
38
2000
Size
hectares
261 554
19 214
782
Number
of reserves
189
187
36
Size
hectares
79 086
5 178
740
Gene conservation units in nature reserves
Certain requirements have to be fulfilled on order for a nature reserve to qualify for being
defined as a gene conservation unit. Minimum requirements for a given species will depend
heavily on a number of factors including its reproductive biology and growth, ecology and
kind of genetic threats it is currently facing or will most likely face in the near future. The
requirements relate to population size, number of reproducing trees, sex ratio and whether
trees are growing in stands or scattered. Conservation of the genetic resources of the
specific species must be in accordance with the original objectives for establishing the nature
reserve. In cooperation with the Directorate for Nature Management and the environmental
units with the County Governor, the Genetic Resource Centre has selected candidate nature
reserves for being considered as in situ gene conservation areas for specific species and to
be part of the EUFGIS network. Assessments have been made in the field of the suitability of
the selected reserves.
Image 8. From the nature reserve containing the
northernmost population of Fagus sylvatica in the world.
Photo: Bernt-Håvard Øyen, Norwegian Forest and
Landscape Institute.
16
During the last five years, 22 gene conservation units, comprising nine forest trees species
on a total of 13 682 hectares have been registered and are included in the EUFGIS
database. They are shown in Table 5. The species occur differently in the nature reserves
and they have different requirements for long term existence. As an example, Picea abies is
a highly competitive species that occurs in large stands and with a sufficient sexual
reproduction and natural regeneration capacity. Other species occur as scattered single
trees that may have low competitive ability or may not have a sufficient sexual reproduction,
e. g. Tilia cordata. Management plans for the genetic resource are therefore needed, which
could be included in the management and conservation plan for the nature reserve.
Table 5. Target forest species included within the in situ
conservation programmes. All conservation units
established as part of the European EUFGIS project.
Species
Picea abies
Ilex aquifolium
Ulmus glabra
Fraxinus excelsior
Tilia cordata
Fagus sylvatica
Quercus petraea, Q. robur
Acer platanoides
Number of
conservation
units
5
1
4
3
2
2
3
2
Total area
hectares
13 151
9
189.3
74.2
72.1
25.9
104.5
46.7
The genetic resources for a number of the Norwegian tree species are considered to be vital,
e. g. Pinus sylvestris, Populus tremula, Betula pendula and Alnus glutinosa (Table 1.2); they
have a wide and continuous occurrence and reproduce easily. It is thus assumed that there
is an extensive gene flow among populations and that they maintain a large genetic variation
on a large scale. For such species, with the exception of Picea abies, it has not been found
necessary to establish specific gene conservation units.
Several Sorbus species are endemic to Norway; they often have marginal geographic ranges
and some are considered threatened or exposed (Table 2). Many species comprise a large
and often unique variation that needs special concern. Specific conservation activities are
needed to manage and conserve these unique genetic resources. Based on former field
studies 43 localities where these species occur with high variability or where rare taxa are
found, have been identified and described. Some of these are in protected areas, some of
which are designated for other purposes, but most are not. Protection and management are
proposed for these localities, in some cases in a combination of in situ and ex situ
conservation. Other species for which such strategies should be proposed are Taxus
baccata, Ilex aquifolium and Malus sylvestris.
Priorities in in situ conservation
It is important to obtain full acceptance from the nature reserve managers that the genetic
resources of selected forest tree species should be conserved in nature reserves and that
management may be needed to fulfil also this objective of the reserve. Such management
should be an integrated part of the management plan of reserves that are selected for this
17
purpose. More gene conservation units and more species should be evaluated to be included
in the in situ conservation programme in nature reserves. A better co-operation is needed
between local and regional managers of both protected areas and forests.
Greater public awareness is needed about in situ conservation of vulnerable tree species
and the role of protected areas for such conservation. Information about this function of each
specific reserve should be given, and the on-line databases of protected areas should be
updated with this information. It is important that the Norwegian in situ conservation units at
the marginal range of several tree species, is considered as an integrated part of the gene
conservation efforts across their whole natural range.
Image 9. Taxus baccata trees growing in a nature reserve in West-Norway.
Photo: Tor Myking, Norwegian Forest and Landscape Institute.
18
4. THE STATE OF EX SITU GENETIC CONSERVATION
Ex situ conservation of forest genetic resources in Norway is performed in different ways:
Collections in arboreta and botanical gardens; long-term tests of clones, families and
provenances in research plantations; progeny tests, clonal archives and seed orchards
belonging to the national breeding programme; and seed lots stored at The Norwegian
Forest Seed Center. No in vitro storage for conservation purpose of forest genetic material is
performed in Norway. Facilities for such storage are available, however, both at research
institutions and private companies.
Arboreta and botanical gardens
Several arboreta and botanical gardens possess collections of forest trees, of both native
and exotic species. In most cases these collections contain a small number of individuals of
each species and do not have a strategy for long term regeneration. Therefore, they are not
considered as the main elements of the national conservation strategy. Such collections
often contribute to the maintenance of unique and rare genotypes, but may also contain
locally adapted populations of native species and individuals from transferred provenances of
native or exotic species. Collections of trees in arboreta often have a role as public parks and
are important for raising public awareness. They are therefore valuable for demonstration
and education. A collection of endemic Sorbus species covering nearly 200 accessions has
been established in a cooperative project between arboreta and botanical gardens. With a
few exceptions, collections in arboreta and botanical gardens are not discussed further in this
report.
Image 10. Columnar forms of Juniperus communis of Norwegian origin in the collection at the Norwegian
University of Life Science. Photo: Jeanette Brun, The Norwegian University of Life Science.
19
Collections for landscaping purposes
A substantial number of trees of both native and exotic origins are planted in the landscape;
in parks, along the roadside and in private gardens. Cultivars and clones with specific
aesthetic values have been developed, tested and propagated for use in such plantings. For
Norwegian conditions, testing for frost hardiness is of specific importance. Collections of
such materials, intended both for testing and demonstration purpose, contain valuable
genetic resources. They offer a large variety of genetic materials and contribute towards
increasing the diversity of tree plantings in the landscape. The largest collection, located at
the Norwegian University of Life Sciences, contains trees of approximately 120 different
species of the genera Acer, Alnus, Betula, Carpinus, Fraxinus, Prunus, Quercus, Sorbus,
Tilia and Ulmus. However, only a small number of trees of each genetic unit has been
planted, in most cases four, and the long term conservation of the materials is not secured.
Smaller collections exist in other parts of the country.
Long-term tests of clones, families and provenances in research plantations
The first provenance and species trials with both native and introduced tree species, in
particular conifers, were planted in Norway approximately 100 years ago. They have given
valuable information about the use of species and provenances. Research plantations were
often planted in experimental designs that were not suitable for long term studies, and few of
the old trials exist to-day. During the last 50 years, most field trials have dealt with the most
important native conifer, Picea abies, and many of these tests are kept and constitute
valuable genetic resources containing genetic units from which genetic information on
phenotypic traits is available. In years with abundant flowering, seed lots were obtained from
several individual trees in a number of natural populations that often were distributed along
climatic gradients, and progeny tests were established. Several such collections were made
by the Norwegian Forest and Landscape Institute, formerly Norwegian Forest Research
Institute, during the period 1951-97. The more recent trials with Picea abies were based on
families from controlled crosses, and also some with clones, with the objectives of
characterizing the genetic variability and inheritance patterns of the species, both within
natural and in breeding populations. A Nordic database of research field experiments with
forest trees (http://noltfox.metla.fi) lists 230 field trials in genetics and tree breeding in
Norway, of which 160 are species or provenance trials, 63 are progeny tests and 4 are clonal
tests. Three institutions are responsible for the field tests in forest genetic research: The
Norwegian Forest and Landscape Institute, The Norwegian University of Life Sciences and
The Norwegian Forest Seed Center. Table 6 presents species that are contained in ex situ
collections that are not part of the tree breeding activities. A large number of short term tests,
often on agricultural soil and with an expected duration of less than 10 years are not
included.
20
Table 6. Species stored in field collections in research or clone banks that are not part of the breeding
programmes.
Species
Field collections 1)
Scientific name
Native
(N) or
exotic
(E)
Picea abies
Pinus sylvestris
Picea sitchensis
Pinus contorta
Picea engelmannii
Picea glauca
Picea mariana
Abies lasiocarpa
Abies grandis
Abies procera
Pseudotsuga menziesii
Betula pendula,
B. pubescens
Querqus petraea
Tilia cordata
Sorbus meinichii
N
N
E
E
E
E
E
E
E
E
E
N
Collections,
provenance or progeny
tests, arboreta or
conservation stands
No.
No.
stands
accessions
114
> 600
6
20
11
> 100
37
> 60
3
20
4
20
4
20
7
20
1
16
2
20
7
75
6
70
N
N
N
1
17
2
40
Clone banks
No.
banks
No.
clones
1
103
1) Materials and field tests in tree breeding are listed in Table 12 and should be added to those
listed here to obtain the total number of ex situ collections.
Clonal archives and seed orchards
Forest tree breeding with Picea abies started in the mid 1950’s with the selection of plus
trees in natural populations. These plus trees were grafted in clonal archives and seed
orchards. Seed lots were collected from the selected trees, either in the forest or in the clone
collections, or controlled crosses were made on the grafts. The resulting families were
planted in progeny tests at multiple sites. Altogether, 5186 plus trees of Picea abies were
selected and kept as grafts in clonal archives or seed orchards, and 3832 families are being
tested in progeny tests. The The Norwegian Forest Seed Center is responsible for all
breeding materials. More information about materials conserved ex situ in tree breeding is
given in Chapter 4.
Seed lots in storage
The Norwegian Forest Seed Center is responsible for the procurement, storage and trade of
seeds for the forest sector. Seeds of recommended seed sources and of both native and
imported species are stored, with main emphasis on a wide selection of native Picea abies
provenance and seed orchard seed lots and Pinus sylvestris provenances, as shown in
Table 7. Long term seed storage is needed as seed years are scarce at northern latitudes
and at high altitudes. Seed lots are therefore kept as long as 20-30 years until new
representative seed crops become available. Optimal storage conditions will guarantee a
high germination rate even after several decades of storage. This seed storage is an
21
important component in the management of the forest tree genetic resources in artificial
regeneration. Samples of some seed lots of native species are saved for long term storage.
Table 7. Accessions of forest tree species stored at The Norwegian Forest Seed Center.
Source: The Norwegian Forest Seed Center.
Native species
Acer platanoides
Alnus glutinosa
Alnus incana
Betula pendula
Betula pendula carelica
Fraxinus excelsior
Picea abies
Pinus sylvestris
Number of
accessions
3
2
2
10
1
3
359
196
Exotic species
Abies amabilis
Abies balsamea
Abies bornmulleriana
Abies concolor
Abies fraseri
Abies homolepis
Abies koreana
Abies lasiocarpa
Abies nordmanniana
Abies procera
Abies sachalinensis
Abies sibirica
Abies veichi
Chamaecyparis lawsoniana
Larix kermpferi
Larix sibirica
Picea engelmanii
Picea glauca
Picea lutzii
Picea mariana
Picea omorika
Picea pungens
Picea sitchensis
Pinus aristata
Pinus cembra
Pinus contorta
Pinus mugo
Pinus pumila
Pseudotsuga menziesii
Thuja occidentalis
Thuja plicata
Tsuga heterophylla
Tsuga mertensiana
22
Number of
accessions
1
1
1
2
2
1
3
24
3
11
2
1
1
1
3
2
1
1
2
1
4
2
9
1
1
5
9
1
3
1
1
1
1
Image 11. Seed lots stored at the Norwegian Forest Seed
Center. Photo: Ragnar Johnskås, The Norwegian Forest
Seed Center.
Documentation and characterisation
Information about the genetic units tested in research and breeding plantations and records
of traits measured are kept in databases at the institutions that established these plantations.
A common database of all genetic units available in research and tree breeding is being
developed as a common project between The Norwegian Forest Seed Center and the
Norwegian Forest and Landscape Institute. Documentation and discussion of the genetic
knowledge obtained in research is presented in articles and reports published both in
international and national journals.
Documentation and information about available seed lots stored at The Norwegian Forest
Seed Center is available at the home page of the institution (www.skogfroverket.no) for
registered users.
Priorities for future ex situ conservation actions
It is proposed that seed samples of forest tree species should be deposited and stored in
Svalbard Global Seed Vault (SGSV), owned by the Norwegian government and managed by
the Nordic Genetic Resource Center. Initially, accessions should be of Picea abies and Pinus
sylvestris of Nordic origin provided by Nordic seed banks, breeding, research or gene
conservation organisations. Such storage could serve three main objectives:
• Conservation of seed samples from natural populations to secure back-up storage for
future monitoring of long-term changes in genetic diversity
• Conservation of seed samples from different stages and generations of breeding
populations or seed orchards to monitor changes in genetic diversity taking place
during breeding operations
23
•
Conservation of back-up seed samples of threatened populations, of gene reserve
forests or other in situ conservation units.
Further plans for such storage at SGSV are being developed.
Depending on results from inventories made in situ of species growing as scattered trees, e.
g. Sorbus species, Taxus baccata, Ilex aquifolium and Malus sylvestris, proposals will be
made for establishing ex situ collections, as mentioned in Chapter 2.
Challenges in ex situ conservation
There is no complete catalogue of all the materials contained in ex situ collections and no
evaluation has been made to assess which material should have highest priority in ex situ
conservation. Management is required in order to maintain collections in long term field trials.
At the time field trials must be thinned and finally harvested, decisions must be made for
further conservation of the genetic materials. Strategies for ex situ conservation of the
genetic resources of species threatened by diseases, the present ash decline taken as an
example, should be developed.
Image 12. Svalbard Global Seed Vault is
located in a mountain at latitude 78
degrees north.
Image 13. Seed lots are stored in closed boxes at
minus 18 degrees Celsius in the Seed Vault.
24
5. THE STATE OF USE AND SUSTAINABLE MANAGEMENT
OF FOREST GENETIC RESOURCES
Forest genetic resources in Norway are used in production forestry when forests are
regenerated after harvest, in afforestation on treeless land or for the replacement of other
tree species. They are also used for Christmas tree and greenery production, for landscaping
purposes or for ornamental use in gardens.
The Forestry Act requires that regeneration generally should take place within three to five
years after harvest, depending on environmental conditions. The local forest authority is
mandated to demand that the forest owner takes actions to establish a commercially viable
stand within a reasonable period of time. Regulations are given for silvicultural and
environmental actions in the regeneration, such as change of tree species, the introduction of
exotic species, the transfer of provenances and the recommended number of seedlings
planted per hectare.
In production forestry, regeneration after harvest is executed differently for the two major
commercial species, Pinus sylvestris and Picea abies. Pinus sylvestris is to a large extent
naturally regenerated, using the seed-tree method. In the regeneration fellings, 30-150 seed
trees are retained per hectare, depending on site conditions. On sites with difficult
regeneration conditions due to. e. g. harsh climate and/or thick humus layers, soil
scarification may be used to improve seedling establishment. The use of soil scarification is,
however, less common in Norway than in the other Nordic countries.
Image 14. Seed trees of Pinus sylvestris left for natural
regeneration. Photo: Sverre Skoklefald, Norwegian Forest and
Landscape Institute.
Picea abies is regenerated both naturally and artificially by planting. When natural
regeneration is planned, the use of patch clear-cuts and shelterwood fellings are common.
When using the latter method, 150-400 trees are retained per hectare for seed dispersal and
to provide shelter. The shelter trees can also be other tree species than Picea abies. At
higher elevations, a significant proportion of the spruce forest is also harvested by means of
mountain forest selective cutting, where subsequent recruitment is initiated by either natural
regeneration or planting, or a combination of both. However, clear-cut fellings and
25
subsequent planting of seedlings is most common in Picea abies and is considered to be the
fastest regeneration method on most forest sites.
National assessments are annually made of the regeneration methods used and the results
of the regeneration three years after harvest. In the assessment made in 2010 of the areas
harvested in 2007, planting was the used regeneration method on 52.5 % of the area, while
10.2 % was regenerated by a combination of planting and natural regeneration. On 26.6 % of
the harvested areas treatments were initiated to favour natural regeneration. No actions were
initiated to re-establish the forest on 10.6 of the area, which is a reduction compared to
earlier years. Approximately 75 % of the planted areas had a seedling density equal to or
higher that that recommended in the legal regulations.
5.1. Reproductive material in use
The number of seedlings delivered from Norwegian forest nurseries and planted in
production forestry has been strongly reduced during the last 20 year period. From a level of
close to 50 million seedlings 20 years ago it has been reduced to an average of 23 million
during the last five–year period, as shown in Figure 6. As seen from the figure, more than 90
% of the seedlings are Picea abies.
The seedlings are produced in 15 forest nurseries which are located in different parts of the
country. In general, each nursery produces seedlings for its local region. Most of the
seedlings are one- or two year-old container plants.
60 000
Other
50 000
Pinus sylvestris
40 000
Picea abies
30 000
20 000
10 000
0
1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010
Figure 6. Number of seedlings delivered from Norwegian forest nurseries 1994-2010. Source: The Norwegian
Forest Seed Center.
26
Image 15. Production of two-year old container seedlings in a Norwegian nursery.
Photo: Ola Gram Dæhlen, Oppland Forestry Society.
The seeds used in the forest nurseries are delivered by the Norwegian Forest Seed Center.
Table 8 presents the mean annual weights of seeds sold, by species, of domestic sources
and imported and exported, as an average of the five-year period 2005-2009. The
dominating species is Norway spruce, covering 81 % of the overall domestic seed sale, and
90 % of seed sold for the purpose of timber and pulpwood production.
Table 8. Seed sold domestically and transferred internationally annually for the period 2005-2009. Source: The
Norwegian Forest Seed Center.
Species
Scientific name
Picea abies
Pinus sylvestris
Picea sitchensis
1)
Picea lutzii
Larix kaempferi
Larix sibirica
Abies lasiocarpa
Abies nordmanniana
Weight of seed
Kg
Native
(N) or
exotic
(E)
N
N
E
E
E
E
E
Domestic
seed
sale
290.8
15.6
1.2
0.01
2.0
2.4
24.7
0.3
1.1
2.8
0.6
14.2
E
10.9
9.6
Purpose (relates to columns
domestic seed sale and
import, not export)
International
transfer
Import Export
0.5
4.4
1.6
1.9
1.7
0.4
11.2
Forestry; timber and pulpwood
Forestry; timber and pulpwood
Forestry; timber and pulpwood
Forestry; timber and pulpwood
Forestry; timber and pulpwood
Forestry; timber and pulpwood
Non-woods forest product,
Christmas trees
Non-woods forest product,
greenery
Forestry; timber and pulpwood
Forestry and landscaping
Other conifers
E
10.6
37.1
32.7
Broadleaves, except Q.
N
4.1
0.5
0.5
petraea and Q. robur
Q. petraea and Q.
N
18 475
robur
1) Picea lutzii is the hybrid between P. sitchensis x P. glauca, from uncontrolled hybridization.
27
Forest reproductive materials are in Norway classified in the categories of the OECD Forest
Seed and Plant Scheme: source-identified, selected and qualified. Recently, seeds have also
been available of the tested category. Import of seeds of Picea abies, which was quite high
50 years ago, is now at a low level. Figure 7 shows the development in the sale of seeds
from source identified and selected (stand seed) and seed orchards (qualified). The
percentage of seeds from seed orchards has increased considerably during the last five
years, in particular in the southern part of the country, where seed orchard seed sold during
the last two years amounted to 75 % of the Picea abies seed sold, and with a percentage
close to 100 in south-eastern Norway.
900
800
700
600
Stand seed
500
400
Seed orchard
seed
300
Total
200
100
0
1996 1998 2000 2002 2004 2006 2008 2010
Figure 7. Sale of seed in kg of Picea abies 1996-2011distributed in classes of stand seed and seed orchard
seed. Source: The Norwegian Forest Seed Center.
Regions of provenance and transfer rules
Formerly, most reproductive material of Picea abies was of the category source identified,
collected in natural stands and characterized by its region of provenance (Figure 8).
According to regulations mandated in the Forestry Act, transfers within the country should
not be made more than 200 km north or south and less than 300 m in altitude. In addition to
the national seed sources of Norway spruce, up to the 1980s transfers were made of
provenances from Central Europe. During the last 20-year period, the far largest part of
Picea abies seed used has been from sources of native origin. However, in western Norway,
where Picea abies did not occur naturally, provenances from Central Europe are
recommended due to their superior volume growth in the coastal areas.
28
Figure 8. Regions of provenance in Norway (red borders) and breeding zones according to the revised breeding
strategy from 2010. The regions of provenance are in addition characterised by the altitude in 100 m intervals.
Source: The Norwegian Forest Seed Center.
Reproductive materials available
All reproductive materials are available at The Norwegian Forest Seed Center for both
national and international requests, both for commercial use and for research (Table 9). If
there is lack of seeds of specific seed lots, Norwegian buyers will have first priority.
29
Table 9. Types of reproductive material (seed lots) available.
Species (scientific name)
Picea abies
Pinus sylvestris
Pinus contorta
Picea sitchensis
Abies lasiocarpa
Betula pendula
Type of
reproductive
material according
to OECD
1)
Scheme
Source identified,
qualified and
tested
Source identified
and qualified
Qualified
Qualified
Qualified
Qualified
Available for both
national and
international requests
Commercial
X
Research
X
X
X
X
X
X
X
X
X
X
X
1)
Categories according to the OECD Scheme;
Source identified: seeds from forest stands in known region of provenance
Qualified: seeds from untested seed orchards that may be under test.
Tested: seeds from tested seed orchards.
5.2. Tree improvement programmes and their implementation
Tree breeding activities in Picea abies started in Norway more than 60 years ago with the
selection of plus trees in natural stands, and grafted seed orchards were established in the
1960s and 1970s. Breeding activities were also initiated with other species (Pinus sylvestris,
Picea sitchensis), but with a lower intensity than for Norway spruce. The selected plus trees
were kept as grafts in the seed orchards or clonal archives, and a progeny testing
programme was slowly initiated. The earliest established seed orchards are now terminated
or are re-established with parents that are being tested in progeny tests. The species
involved in the breeding, their priority and the number of seed orchards are listed in Table 10.
In addition to breeding for timber and pulpwood, Christmas tree production is an important
objective. All Norwegian seed orchards are still of first generation breeding populations, but
with increasing number of the tested category. The orchards for Pinus contorta and Betula
pendula are seedling seed orchards, the rest are grafted clonal orchards. In addition to the
clonal seed orchards listed for Picea abies spruce, two seedling seed orchards intended for
producing seeds for Central Norway and three seedlings seed orchards for Northern Norway
were recently established. These are not included in Table 10 as they will not produce seeds
until 30-40 years from now.
A revised tree breeding strategy
A new national tree breeding strategy for the period 2010-2040 has been developed during
the last four years and has been on a hearing process involving organisations in practical
forestry, environmental management, forest authorities at national and local level, research
organisations and universities. The strategy will be revised at ten year intervals, and five-year
action plans will be made for each breeding zone.
30
Table 10. Forest improvement programmes in Norway. All seed orchards are first generation. Source: The
Norwegian Forest Seed Center.
Species
Picea abies
Native (N) or
Exotic (E)
N
Abies lasiocarpa
E
Alnus glutinosa
Pinus sylvestris
Picea sitchensis
Picea lutzii
Picea engelmanni
Pinus contorta
Larix sibirica
Betula pendula
N
N
E
E
E
E
E
N
Improvement programme
objective
Timber and pulpwood,
Christmas trees
Non-woods forest product,
Christmas trees
Timber and pulpwood
Timber and pulpwood
Timber and pulpwood
Timber and pulpwood
Christmas tree
Timber and pulpwood
Timber and pulpwood
Timber and pulpwood,
landscaping
Priority
High
Seed orchards
Number Area (ha)
15
146.8
High
3
1
Medium
Low
Low
Low
Low
Low
Low
Low
2
2
2
1
1
1
1
1
1
5
10
0.7
2.2
7
0.5
1
Main priority in breeding is given to Picea abies and Abies lasiocarpa (Table 10). The
proposed breeding objectives for Picea abies are to improve climatic adaptation, growth and
quality, without decreasing the genetic variation in future forests. Bred material should
provide higher survival and be possible to use over a larger area then material from natural
stands. The bred material should also be robust to future climatic changes. The increased
growth should contribute to mitigate the effect of CO2 from the atmosphere. Breeding should
not decrease, and preferably increase, wood density, improve form stability and reduce the
frequencies of defects that cause reduced value production. Except for one breeding zone,
G0 for the mildest climatic conditions along the coast, breeding is performed on material from
native provenances. A high level of genetic diversity is kept in the breeding programme of
Picea abies by having several breeding zones, several subpopulations within each zone and
a sufficient number of individuals within each population.
Image 16. A Picea abies seed orchard. Photo: Ragnar Johnskås, The Norwegian Forest Seed Center.
31
Breeding and deployment zones
Norway is divided into eight breeding zones (Table 11) based on latitude, altitude, and known
climatic gradients, both for administrative reasons and optimal use of adapted reproductive
materials from the seed orchards. Breeding efforts and objectives differ between zones
depending on whether there are specific issues in the wood production that have to be
focused, and also on the importance of forestry in the region. In each zone the breeding
population is divided into one or more sub-populations each containing 50 unrelated
individuals. Breeding zone G0 will contain one sub-population with individuals selected from
more southern provenances adapted to climatic conditions corresponding to a 2º C increase
in mean annual temperature in zones G1 and G4. The other zones will contain subpopulations with individuals from a limited geographic area within the zone. Hence, the
populations should then be adapted to the present climate in the zone, but may also be
ranked according to climatic gradients within the zone. They should provide the basic
material for reproductive material from seed orchards that could be used in a wide area, but
also be flexible for transfer if climate change. All individuals in the sub-populations should be
tested in progeny tests planted at several sites. The importance of traits in selection will vary
among zones, but will generally characterise annual growth rhythm, height growth and wood
quality traits. The timing of flushing in spring is a key trait in regions where spring frosts
frequently occur and early flushing will be avoided. The recommendations for the deployment
of reproductive material should be revised as more fields test information become available.
It is important to note that breeding zones and deployment zones for seed orchards are
different and that there can be several deployment zones within each breeding zone. The
deployment zones are defined by the adaptive properties of the seedlings from each seed
orchard which have to be tested. Their performance will to some extent be influenced by the
seed orchard locality due to both pollen contamination from surrounding forests and by
epigenetic effects caused by the climatic conditions at the seed orchard site.
Table 11. Breeding zones and regions of deployment for Picea abies in Norway. In each breeding zone there are
one or more sub-populations each containing 50 unrelated individuals from a limited geographic area within the
zone.
Breeding
zone
G0
G1
G2
G3
G4
G5
G6
G7
Region of deployment
Altitude
Same as G1 and G4 with a 2º C
increase in mean annual temperature
Interior south-eastern Norway
Lat. 58º - 62º N
Interior south-eastern Norway
Lat. 58º - 62º N
Interior south-eastern Norway
Lat. 58º - 62 ºN
Western Norway
Lat. 58º - 62 ºN
Central and northern Norway
Lat. 62º - 66º30‘N
Central and northern Norway
Lat. 62º - 66º30‘ N
Northern Norway
Lat. 66º30’ - 70ºN
32
Number of subpopulations
0 – 250 m
0 – 350 m
1
5
350 – 650 m
4
650 – 950 m
4
0 – 350 m
2
0 – 250 m
3
250 – 550 m
3
0 – 250 m
1
Genetic improvement materials and trials
Table 12 presents field plantings containing materials that that are part of the breeding
programmes. The most extensive breeding material exists for Picea abies with more than
5000 plus trees grafted in clonal archives and seed orchards and a large number of progeny
trials of different ages. With this species and with Pinus sylvestris and P. contorta
provenance trials were formerly done as part of the genetic research programme. For the
other species with high priority, Abies lasiocarpa, the trials were established more recently.
Table 12. Tree improvement materials and trials that are part of the breeding populations.
Source: The Norwegian Forest Seed Center.
Species
Scientific name
Picea abies
Abies lasiocarpa
Alnus glutinosa
Pinus sylvestris
Picea sitchensis
Picea lutzii
Picea engelmanni
Pinus contorta
Larix sibirica
Betula pendula
Native
(N) or
exotic
(E)
N
E
N
N
E
E
E
E
E
N
Plus
trees
Clonal
archives
Number
Number
5186
15
1
100
150
168
50
76
Provenance trials
Progeny trials
Number
of trials
Number
of prov.
Number
of trials
Number
of
families
9
76
11
148
6
1
3832
20
121
1
11
2
17
1
1
6
213
15
99
5
15
1
225
3
22
200
Image 17. Short term progeny test with Picea abies
on cultivated soil. Photo: Norwegian Forest and Landscape institute.
33
Benefits from breeding
Results from field trials suggest that seedlings of Picea abies from seeds produced in
untested seed orchards will have 10-15 % better height growth when the stand closes, and
similar or better quality, compared to seedlings from stand seed. The gain from seed
orchards with material tested in progeny tests will increase with additional 10 %. This will
contribute to an increase in the value of the forest, and it has been estimated that the
planting of 40 million seedlings from seed orchard seed will result in an extra uptake of one
million tons of CO2.
Information system on tree breeding and choice of reproductive material
The use of high quality reproductive seeds and seedlings is highly recommended and
measures are taken to ensure that the tree planters actually use the materials. All information
about reproductive materials available is presented at the website of the Norwegian Forest
Seed Center: www.skogfroverket.no. At this page advice is given for recommended
materials for a planting site defined by region and community, latitude and altitude. It is
planned that nurseries producing seedlings of the different seed lots for sale will be listed.
Another web site, www.skogplanteforedling.no, presents information about the national tree
breeding programme, its strategies, objectives and seed orchards. Research results
important for the breeding and also for motivating the foresters to use the materials are
presented in a popular form.
Challenges in the use of forest genetic resources
Ten years ago there was a substantial decrease in the number of seedlings planted in
Norwegian forestry. The main reason for this was the removal of subsidies given to the forest
owner for planting. The number of seedlings planted has remained at this low level during the
last ten year period. The national strategy to increase CO2 sequestration by greatly
augmenting the number of genetically improved seedlings planted will require a considerable
increase in resources invested into tree breeding and associated breeding research. In
addition to governmental funding, a substantial increase in the contributions from forest
organisations and forest industry will be required. It will be necessary to educate tree
breeders and scientists in forest genetics. An increased cooperation among the Nordic tree
breeding organisations will be beneficial for obtaining better adaptation to the changing
climate in the future forest and for higher production.
34
6. THE STATE OF NATIONAL PROGRAMMES, RESEARCH,
EDUCATION, TRAINING AND LEGISLATION
Norway does not have one single formalized national forestry programme, but several
parallel processes and documents jointly constitute the national forest programme. The most
important elements are the Forestry Act (2005), the white paper on climate challenges in the
agricultural sector (2009), the white paper on forest policy (1999), the annual national
budget, the forest policy instruments and the Living Forest Standard, which is a national
standard for sustainable management in Norway. Since June 2010 the Living Forest
Standard has been suspended, pending an unsolved disagreement in the Living Forest
Council related to reforestation and afforestation involving the use of new and introduced tree
species. Although formally suspended, the forestry sector continues to follow the rules and
guidelines of the standard. Forest genetic resources, and their conservation and use, are
explicitly mentioned in several of these policy documents, both in general terms and in
recommendations related to the production and use of forest reproductive material and in the
implementation of important measures to mitigate climate change. Genetic resources are
also specifically treated in the Nature Diversity Act adopted by the Parliament in 2009. This
act regulates the conservation, access and use of genetic resources from nature, and also
the import and release of alien organisms in Norwegian nature. The Government has
recently presented a white paper on agriculture and food in Norway in which it is proposed to
produce an annual report on sustainable forestry from 2013. This report will possibly also
include use of forest genetic resources.
6.1. National programme on forest genetic resources
The Norwegian programme on forest genetic resources was initiated in 2001 when a national
FGR advisory committee was appointed by the Ministry of Agriculture and Food and with a
secretariat hosted at the Norwegian Forest Research Institute (which later was merged into
the Norwegian Forest and Landscape Institute).
The first advisory committee consisted of representatives from research institutions, the tree
breeding organisation, the forest owners’ organisation and national and regional authorities
within forest and nature management. This secured a broad scope and anchoring of the
national FGR-activities to user groups and stakeholders. A national programme for 20032006 was approved by the committee.
An evaluation of the national management of genetic resources for food and agriculture
resulted in the establishment of the Norwegian Genetic Resource Centre in 2006 as a
department of the Norwegian Forest and Landscape Institute. National programmes for
animal, plant and forest genetic resources were merged in the centre.
The Norwegian Genetic Resource Centre
The Norwegian Genetic Resource Centre promotes the conservation and sustainable use of
national genetic resources in farm animals, crop plants and forest trees. It is the national
centre of expertise on genetic resources in agriculture, advisory to the Ministry of Agriculture
and Food, and coordinates a wide range of activities.
35
The Centre is the secretariat for advisory committees within each of the three sectors for
farm animals, crop plants and forest trees. Together with these bodies, the Centre conducts
national programmes for conservation and sustainable use of genetic resources in
agriculture and is responsible for the execution of the national programmes for animal, plant
and forest genetic resources.
The Centre initiates and administrates activities within the three sectors, but depends on
cooperation within gene conservation networks for practical implementation of the
programmes. It contributes towards increasing the information flow on genetic resources and
general public awareness. It is also the national participant in Nordic and international
programmes.
The Genetic Resource Centre is financed under the budget of the Norwegian Forest and
Landscape Institute by the Norwegian Ministry of Agriculture and Food, amounting to
approximately 10.5 million NOK per year. Of this amount, 2 million NOK is provided to
activities related to forest genetic resources.
The main responsibilities for the FGR advisory committee, to be followed up by the forest
section at the centre are:
1. Carry out The Norwegian Action Plan for Conservation and Use of Forest Genetic
Resources 2011-2014
2. Coordinate national activities and initiate new projects aimed at conservation and use
of FGR
3. Develop further cooperation with institutions, organisations and individuals regarding
FGR
4. Ensure dissemination of knowledge, promote capacity building and raise public
awareness about FGR.
Priorities of the national FGR programme
The national programme for forest genetic resources runs in four-year cycles. In the first two
periods from 2003 the following activities were given high priority:
• Organisation and establishment of a national network
• Documentation of knowledge about national FGR
• Establish databases of protected areas containing populations of forest trees species
• Monitoring the genetic resources of selected broadleaved tree species in the regular
sample plots of the National Forest Inventory
• Initiate research on characterization of genetic variability of forest tree species
• Ex situ conservation in collections and in breeding populations
• In situ conservation in protected areas
• Public awareness activities
• Promoting new enterprises based on FGR
• Questions related to legal rights to FGR.
36
In the current action plan for the period 2011-2013 the planned actions are in four major
areas:
• Generate knowledge and monitor processes influencing genetic resources
• Ex situ and in situ conservation activities
• Sustainable use and development of FGR
• Networking, coordination and dissemination of knowledge about FGR and raising
public awareness.
Main activities are presented in Table 5.1.
Major challenges in the national programme
For most of the national tree species genetic is scarce and the generation of better genetic
information should have high priority. This is in particular important in view of the changing
climate conditions, both for the development of adapted reproductive material for the
commercial species and for the management of forest tree genetic resources in general.
Monitoring of the development of changes in genetic diversity to be able to actuate specific
conservation activities when needed, is another challenge. This is in particular important for
rarer forest trees species and for their conservation in situ, which requires sustainable
management in nature reserves, or specific ex situ conservation actions.
A large number of actors collaborate in the national programme; in nature and forest
management and administration, research, tree breeding and the users of the genetic
resources. Agreements on common objectives and how to achieve these objectives are
needed for the success of the programme.
6.2. Partners in the national FGR programme
The staff of the Norwegian Genetic Resources Centre comprises five persons, and only 0.5
of a man-year is dedicated to the forest sector. Accomplishment of the national program is
therefore highly dependent on synergies and close cooperation with a broad range of
partners. The partners can be grouped in two types, those that have FGR activities as a main
activity and cooperative partners on specific activities. The partners and their related tasks
can be summarised in the Table 13. National coordination of activities is done by the
Norwegian Genetic Resource Centre, at the Norwegian Forest and Landscape Institute.
The main actors with specific responsibilities in the conservation of FGR, in addition to the
Norwegian Genetic Resource Centre, are the Directorate for Nature Management for
maintaining natural populations and the Norwegian Forest Seed Center for the utilisation of
FGR. The national seed bank is located at the latter institution and performs activities related
to seed collections, seed cleaning and processing, seed sales to nurseries and forest
owners, import and export, official statistics, seed certificates and tree improvement and
seed orchard management.
The national programme supports every year projects carried out in partner institutions
based on funding by the Ministry of Agriculture. The average annual programme budget for
such projects has amounted to approximately 1.1 million NOK during the last four-year
period.
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Table 13. Activities and cooperating partners in the Norwegian FGR programme.
Cooperative tasks/activities
Partner
In-situ conservation of FGR in natural
populations, management included
Directorate for Nature Management; Regional
authorities within forest and environmental
management
Ex-situ conservation in collections
Department of Plant and Environmental Sciences,
Norwegian University of Life Sciences; botanical
gardens; arboreta; museums; Nordic Genetic
Resource Center (SGSV), Norwegian Forest Seed
Center
Norwegian Forest and Landscape Institute;
Department of Ecology and Natural Resource
Management, Norwegian University of Life
Sciences; Norwegian Forest Seed Center
Norwegian Forest and Landscape Institute;
Norwegian Forest Seed Center; University of Life
Sciences; Norwegian Institute of Agricultural and
Environmental Research; arboreta and botanical
gardens; forest nurseries and forest plant societies
Norwegian Forest and Landscape Institute;
universities; Norwegian Biodiversity Information
Centre; Norwegian Institute for Nature Research
Norwegian Forest and Landscape Institute;
Norwegian Forest Seed Center; owners of
collections; forest owners
Norwegian Research Council; Norwegian Forest
and Landscape Institute; Norwegian Institute of
Agricultural and Environmental Research;
Norwegian Institute for Nature Research;
universities
Norwegian University of Life Sciences
Ex-situ conservation in research and tree
breeding
Development of climatically adapted
forest reproductive materials
Monitoring of rare and threatened
species and populations
Documentation and databases
Research in forest genetics and FGR
Teaching in forest genetics and FGR
Business enterprise based on FGR
National legislation and legal questions
related to FGR, import/export, including
access and benefit sharing
Information and public awareness
Norwegian Forest Seed Center; other R & D
institutions; forest nurseries; economical
organisations in forestry and private enterprises
Ministry of Agriculture and Food; Ministry of the
Environment; Directorate for Nature Management;
Committee for the Control of Forest Reproductive
Materials; Norwegian Food Safety Authority;
Fridtjof Nansen Institute
Cooperative R & D institutions and project partners
6.3. Research, education and training
The major part of the research on forest genetic resources is performed by the Section on
forest genetics at the Norwegian Forest and Landscape Institute. Some research projects are
also performed at the Norwegian Institute of Agricultural and Environmental Research and at
the universities. The projects are finances either by the institution’s own budget or by
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research grants given by the Norwegian Research Council, the Nordic Council of Ministers
and the European Union. At the Norwegian Forest and Landscape Institute the budget for
forest genetics research amounts approximately NOK 7.5 million (2011), which is close to 10
% of the total budget for forest research at the institute.
Advanced education in topics related to agriculture and forestry at university level is the
responsibility of the Norwegian University of Life Sciences. Their courses include basic
genetics, population and quantitative genetics, molecular genetics and plant breeding. Forest
genetics and tree breeding is included as part of the basic course in silviculture and in the
general course at the master level. In the basic course students visit the Norwegian Forest
Seed Center and a seed orchard. No national course is given in forest genetics or forest
genetic resources at the doctorate level. However, PhD students in this field could follow
courses given in plant breeding and conservation of plant genetic resources. At the Nordic
level, a doctorate course in plant breeding, where forest tree breeding is included, is given
regularly.
Forest tree breeding and the importance of choosing proper forest reproductive materials is
regularly highlighted at regional and national meetings for nursery managers, the regional
forest extension service and forest owners with contributors from the Norwegian Forest and
Landscape Institute and the Norwegian Forest Seed Center.
In Norway, no specific university courses are offered in forest genetics or management of
forest genetic resources. Therefore foresters and managers of natural resources often do not
understand the values of the conservation and sustainable use of forest genetic resources.
Such courses are therefore needed.
6.4. National legislation
Significant legislation regulating conservation and use of forest genetic resources in Norway
is the Forestry Act and the Nature Diversity Act. A regulation mandated in the Forestry Act
(Regulation on forest seeds and plants) assures that reproductive material of high quality and
adapted to planting site is being used in regeneration and that a high level of genetic
diversity is maintained in the forest. A phytosanitary regulation aims to prevent introduction of
pests and diseases and assures a healthy reproductive material. International trade of forest
reproductive material is regulated by the OECD Forest Seed and Plant Scheme.
The Nature Diversity Act of 2009 contains provisions on forest conservation and on
prioritized species and selected habitats in forests that are important for specific groups of
species. Voluntary protection is now the main strategy for forest conservation. A regulation
under this act will regulate the import and planting of alien plant species, in particular nonnative forest trees. The Nature Diversity Act also regulates access, property rights and
exchange of genetic resources, as further discussed in Chapter 7.
Norway is a member of the UPOV convention of 1978 and the European Patent Organisation
(EPO). However, at present there are no known cases of plant variety protection being
applied for in the forestry sector, nor are there any patents so far. It is foreseen that such
protection can be relevant at least in four cases: Christmas tree production, breeding new
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trees for biofuel production, plantations of tree varieties to capture and store carbon and
breeding tree varieties for making them more tolerant to climate change conditions.
A major challenge as regards legislation is to ensure that knowledge generated from
research is taken into account when laws and regulations are decided, and that both such
knowledge and practical experience are used in the management of the genetic resources. It
is increasingly important to maintain a legal system that facilitates exchange of forest
reproductive material between countries, not the least when considering climate adaptation
and mitigation.
6.5. Public awareness
The national FGR programme has, since its establishment in 2001, emphasised
dissemination of data about forest genetic resources and information about the importance of
their conservation and sustainable use. Several methods and information channels in use:
−
−
−
−
−
−
Website of the Norwegian Genetic Resource Centre; www.genressurser.no or
www.skogoglandskap.no/genressurser which disseminates information about activities in
the national FGR programme including project information and a news service
Website of the Norwegian Forest Seed Center, www.skogfroverket.no, which contains
information about available forest reproductive materials and recommendations for use,
in addition to statistical information
Website related to forest tree breeding, www.skogplanteforedling.no, maintained by the
Norwegian Forest Seed Center, providing knowledge and information about forest tree
breeding in Norway
Conferences, seminars, lectures and meetings targeted at specific stakeholders and user
groups
Interviews and participation in radio programmes, articles in professional magazines,
technical and scientific journals and general media
Production and distribution of posters, brochures and other printed material for the public.
The public awareness of the values related to forest genetic resources has increased
significantly in Norway during the last five year period. However, it will continuously be
necessary to educate managers of forests and natural resources about the importance of
forest genetic resources, and in particular, how to choose adapted reproductive materials
under the changing climate conditions. A major challenge is to promote awareness that long
term considerations are necessary for the management of forest genetic resources. It is also
a challenge to make the results from forest genetic research and their implications known to
the general public.
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7. THE STATE OF REGIONAL AND INTERNATIONAL
AGREEMENTS AND COLLABORATION
According to governmental policy Norway has supported regional and international
agreements and cooperative programs on forest genetic resources and has played an active
role in multilateral bodies and different actions. Regionally, cooperation has been at the
Nordic and Baltic level, and internationally both at the European and global level.
7.1. Nordic cooperation
Nordic collaboration on research, conservation and use of forest genetic resources is an
important component of the cooperation organized and financed by the Nordic Council of
Ministers and its research body the Nordic Forest Research Co-operation Committee (SNS).
From the start in 1972, Norwegian scientists have initiated and been partners in research
and breeding projects in forest genetics and tree breeding.
The Nordic Council for Forest Reproductive Material, established in 1970, organised
cooperative activities to increase the availability of suitable forest reproductive material and
to promote successful forest regeneration in the Nordic countries. In 2008, this body was
merged with the Nordic Gene Bank for agricultural plants and the Nordic Gene Bank Farm
Animals to form the Nordic Genetic Resource Center (NordGen) with the aim to strengthen
and coordinate genetic resource activities in the agricultural sector in the Nordic countries.
The forest sector of NordGen, NordGen Forest, is located at the Norwegian Forest and
Landscape Institute and receives additional economic support from Norway. It serves as a
Nordic forum in the fields of forest genetics and genetic resources, supply of seeds and
plants, and methods for regeneration. The main goal is to contribute to the establishment of
the best possible Nordic forests for the future by organising thematic days, conferences,
seminars and meetings. NordGen Forest monitors and initiates research and development,
and disseminates information. The NordGen Forest network contains two external bodies,
the Council and the Working Group on Genetic Resources, each with members from all
Nordic countries. Information and news related to the forestry activities are presented on the
web page of NordGen (www.nordgen.org) and in publications.
The Council seeks to increase the availability of suitable forest reproductive material and to
promote successful forest regeneration in the Nordic countries. This includes both practical
and administrative parts of seed and plant supply, regeneration methods, genetics and tree
breeding. Its members exchange information on regeneration issues, discuss different topics
of interest to Nordic forestry, and plan coming events.
The Working Group on Genetic Resources ensures co-operation in conservation and use
of genetic resources of forest trees among the Nordic countries. It forms an interface
between conservation activities at the national and the European levels (EUFORGEN), and
initiates and implements activities that can improve or guide the conservation and use of
forest genetic resources.
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NordGen Forest carries out development projects in the field of forest genetic resources.
Titles of projects funded by the Nordic Council of Ministers are: Seeking Appropriate
Legislation Regulating Access and Exclusive Rights to Forest Genetic Resources in the
Nordic Region and Cooperation in breeding of Picea abies. An upcoming project is to
establish long term storage of seeds of forest tree species at Svalbard Global Seed Vault.
7.2. European Networks
Norway has been a member of the European Forest Genetic Resources Programme
(EUFORGEN) since its start in 1994. The programme aims at promoting conservation and
sustainable use of forest genetic resources as well as serving as a platform for panEuropean collaboration in this area, bringing together scientists, managers, policy-makers
and other stakeholders.
EUFORGEN was originally structured in networks for species or groups of species, later
thematic networks were added. In the last phase the mode of operation is based on expert
working groups and workshops to carry our specific tasks related to FGR in Europe. Norway
has actively participated in most of these activities. The country has also contributed data on
24 dynamic gene conservation units of forest trees in Norway to the European Information
System on Forest Genetic Resources in Europe (EUFGIS), developed in close cooperation
with EUFORGEN.
EUFORGEN was established as an implementing mechanism for the resolution conservation
of forest genetic resources of the first Ministerial Conference on the Protection of Forests in
Europe (MCPFE). Norway has continued to play an active role in MCPFE, later named
FOREST EUROPE, through which the European ministers of forestry have committed
themselves to conserve and enhance forest genetic resources as part of sustainable forest
management. In the period 2008-2011, Norway held the chairmanship and secretariat
(Liaison Unit) of FOREST EUROPE, and is from 2011 a bureau member of the
Intergovernmental Negotiating Committee for a Legally Binding Agreement on Forests in
Europe.
Norway has participated in the EU funded Co-ordination Action Treebreedex with participants
from 18 countries and has co-ordinated the activity: Geographic structure of genetic diversity.
The main aim of the project was to develop a scientific and technical research framework in
forest genetics and tree breeding and a virtual tree breeding centre at the European level.
7.3. International programmes and agreements
Norway has signed international agreements and takes part in international processes
relevant to the sustainable use, development and conservation of forests. The United
Nations Framework Convention on Climate Change (UNFCCC) and the Convention on
Biological Diversity (CBD) are of particular importance relative to forest genetic resources.
The country has been an active force in the negotiations in United Nations Forum on Forests
(UNFF) leading to a voluntary agreement at the global level for sustainable management of
forests, and for reducing deforestation of the tropical forests.
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Norway participates actively in the Commission of Genetic Resources for Food and
Agriculture in FAO. The country has been a member of the Intergovernmental Technical
Working Group of Forest Genetic Resources and chaired the first session of this body.
Norway takes an active part in research activities on forest genetic resources initiated by the
International Union of Forest Research Organisations (IUFRO), and Norwegian scientists
have established and maintained tests as part of the international provenance trials with
Norway spruce and Western American conifers. In IUFRO, Norway recently chaired the
Working Party Norway spruce genetic resources for two periods.
7.4 Benefits from and needs in regional and international cooperation
Being a small country with a limited number of actors involved in activities related to the
conservation of forest genetic resources, Norway has benefited from both regional and
international cooperation. At the Nordic level, both forest genetic research and development
projects have dealt with species sharing more or less the same gene pool, and breeding is
based on similar strategies, in particular for Norway spruce. Establishing field trials with the
same materials in several countries and common analyses of data from such experiments,
have strengthened the generality of the results obtained. Some joint Nordic research projects
have further developed into common projects at the European level that have generated new
knowledge. Information exchange, development of technical guidelines and establishment of
gene conservation strategies are activities that have been beneficial in the EUFORGEN
collaboration.
Further cooperation both at the regional and European level is needed in the management of
forest genetic resources under climate change. It is then important to maintain the networks
that have been established in common research and development projects.
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8. ACCESS TO FOREST GENETIC RESOURCES AND SHARING
OF BENEFITS ARISING OUT OF THEIR USE
In 2003, the Nordic Council of Ministers adopted a Nordic Ministerial Declaration on access
and right to genetic resources, in which they declared that the legal status of their forest tree
genetic resources should be evaluated, but did not identify any reasons to recommend
regulations of access.
According to the Convention on Biological Diversity (CBD), each country has a sovereign
right over its genetic resources, including the competence to regulate ownership and access
to its genetic resources. Norway has introduced a specific legal regulation of rights to genetic
resources in general in the Nature Diversity Act of 2009, in which § 57 says: “Genetic
material obtained from the natural environment is a common resource belonging to
Norwegian society as a whole and managed by the state. It shall be utilised to the greatest
possible benefit of the environment and human beings in both a national and an international
context, also attaching importance to appropriate measures for sharing the benefits arising
out of the utilisation of genetic material and in such a way as to safeguard the interests of
indigenous peoples and local communities.” The Act requires issue of a permit prior to
collecting material from nature for the purpose of utilizing its genetic resources.
Even though this Act also includes forest genetic resources, its provisions give an exception
for forest genetic resources and states that “Collection for use in public collections and for
use and further breeding or cultivation in agriculture or forestry does not require a permit.”
Therefore access to propagative material of forest trees may be collected as before for the
purpose of forestry as long as the property rights of the land-owner is respected.
The Public Right of Access allemannsretten ensures by law everyone access to public and
private non-cultivated land and also to forests. This right hold a strong position, closely
related to recreation activities. It provides access to non-cultivated forested land and to some
extent to the forest genetic resources. Forthcoming administrative regulations of the Nature
Diversity Act will further determine regulations which may clarify how far the common rights
to the genetic material extends. This may have implications for the ownership of collected
cones, seeds and breeding material.
Practical cone collection of conifers is organised by local forestry extension officers after
logging in the forest, after an agreement with the forest owner and in most cases without
economic settlements. Breeding materials such as scions for the grafting of plus trees are
collected after permit given by the forest owner. Such permits do not involve economical
compensation to the forest owners. Seeds from the breeding programme are sold without
any restrictions for further use. Tree breeding is partly funded by the income from seed lots
sold to the nurseries and partly subsidised by the Government, and is generally a non-profit
business. Thus, it is the forest owner who obtains the benefits arising from the use of the
forest genetic resources when harvesting the forest 60-100 years after its establishment.
The principle of fair and equitable sharing of the benefits from the use of genetic resources is
established in the Convention on Biological diversity adopted in 1992, and further elaborated
in the Nagoya protocol that was adopted in 2010. A paragraph in the Nature Diversity Act of
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2009 requires that this principle shall be complied with when imported genetic material is
used in Norway. However, except for the purpose of Christmas tree production, international
trade with forest reproductive material has been low in Norway for the last 10 year period and
in particular for the last two years. Thus, there has been no benefit sharing of imported forest
seeds since the CBD came into force.
It is the policy of the Government that native forest genetic resources should be preferred for
use both in forestry and in landscaping, and that the use of exotic trees species should be
restricted in forestry. A proposal to require a permit before establishing stands based on
forest reproductive material not originating from Norway, Sweden or Finland is under
consideration. This restriction towards transfers of forest reproductive material is based on
environmental considerations. It may prevent an optimal choice of reproductive material
under the changing climate conditions.
Both forest seed companies and tree breeders desire to continue the policy of free access to
forest genetic material for seed production and tree breeding. It is believed that free access
produces benefits which gains in the whole forestry chain and contributes to keep seed and
plant cost at low levels. It is recommended that flexible exchange of forest genetic resources
among the Nordic countries should continue. So far, no legal regulations have restricted such
exchange and will most likely not do so in the next ten year period unless new
biotechnological methods appear which might introduce the use of exclusive property rights
also on forest genetic resources. An assessment is planned to find out if it is necessary to
take legal steps to assure that improved forest reproductive material developed in the
national tree improvement programmes also in the future will remain in the public domain.
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9. CONTRIBUTION OF FOREST GENETIC RESOURCES TO
FOOD SECURITY, POVERTY ALLEVIATION AND
SUSTAINABLE DEVELOPMENT
Nationally
No forest tree species are important for food security in Norway. However, the income from
harvesting the forest contributes to the total revenue for many active farmers. The forest
resources are thus important for maintaining a sustainable agriculture and food production
across the country. It is an expressed political aim to strengthen the contribution from the
forests to the economic value creation in agriculture and to reach important goals related to
energy, climate and environmental values. The forests are important for recreational
activities and thus for public health. The Ministry of Agriculture and Food has decided that a
report on sustainable forestry should be published annually from 2013, presenting
information and new knowledge related to forest resources, their use and development and
contribution to the climate, in addition to environmental values. A monitoring will thus be
made of the development of the whole forestry sector, forest genetic resources included.
Globally
Promoting sustainable development and poverty reduction is an overriding objective of
Norwegian foreign and development policy. One major element of this policy is the
Government of Norway’s International Climate and Forest Initiative, in which Norway is
prepared to allocate up to NOK three billion per year to efforts to reduce greenhouse gas
emissions from deforestation in developing countries. The initiative applies to all types of
tropical forests. One of the main goals of this initiative is to promote the conservation of
natural forests to maintain their carbon storage capacity. This initiative will thus contribute to
the maintenance of species and genetic diversity, ecosystem services and livelihoods of
forest dependent indigenous peoples and local communities. It contributes to the UN
Millennium Development Goal 7 on ensuring environmental sustainability and the target
aiming to reverse the loss of forests.
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ACKNOWLEDGEMENT
This report has been prepared by the Norwegian Genetic Resource Centre. Contributions to
the report from Mari Mette Tollefsrud, Tor Myking, Arne Steffenrem, Lars Dalen, Aksel
Granhus, Stein Tomter, Øyvind Edvardsen, Jan Ulitzsch, Per Salvesen, Hanne Hegre
Grundt, Vibekke Vange, Karl-Dag Vorren and Elisabeth Koren and Terje Hoel are gratefully
acknowledged.
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